Capacitive environmental sensing for a unique portable speaker listening experience

ABSTRACT

A networked speaker system automatically adjusts certain audio speaker system settings based on whether the system is inside a building or has been moved outside as may be sensed by one or capacitors on a speaker. Also, techniques are described for adjusting speaker driver direction based on walls or other barriers in a room or based on the location of a listener.

FIELD

The present application relates generally to networked speaker systems.

BACKGROUND

U.S. Pat. Nos. 9,288,597, 9,560,449, 9,866,986, 9,402,145, 9,369,801,9,426,551, 9,826,332, 9,924,291, 9,693,169, 9,854,362, 9,924,286, andUSPP 2018/115,825, owned by the present assignee and all incorporatedherein by reference, teach techniques related to audio speaker systemsand more particularly to wirelessly networked audio speaker systems. Bywirelessly networking speakers in a system, flexibility is enhanced,because users can easily move speakers to locations in buildings as theydesire and otherwise configure the audio system setup without thenuisance of wiring.

SUMMARY

As understood herein, portable wireless speakers within a building canbe easily moved outside by users for entertainment and other purposes.As further understood herein, it would convenient for the user if theaudio configurations of such systems were automatically establisheddepending on the new location/orientation of the various systemspeakers. System speakers include audio speakers per se as well as soundbars, speakers on display devices such as TVs, etc.

One or more capacitors are mounted on a surface of an audio speaker andgenerate signals representative of the nature of the surface on whichthe speaker is disposed and more particularly representative of theelectrical capacitance of the surface, with the frequency response ofthe speaker being established according to the nature of the surface.The capacitance sensor is in contact with the surface material, and thusthe capacitance sensor(s) are located on the speaker in such a way thatone or more sensors make contact with a surface. Multiple sensors can bemounted on respective surfaces of the speaker that might serve as thesurface resting on the floor or ground.

A library of materials is created and stored locally and/or in thecloud, i.e., on an Internet server. The library stores speaker settinginformation such as desired EQ response curves and correlates or linksthat information to various types of surface material. The signal fromthe sensor is correlated to a surface type and then the library isentered using that type to retrieve the setting information and applythe setting(s) to the speaker. If a local library does not containsufficient information, an Internet library may be accessed. Or, logicdescribed in FIG. 8 below may be used. Or, techniques described inpresent assignee's patent application entitled “Frequency Sweep for aUnique Portable Speaker Listening Experience”, filed Jul. 2, 2018 asU.S. patent application Ser. No. 16/025,874, and incorporated herein byreference, may be used.

The above calibration can be induced via mechanical switch, virtualswitch, voice command, proximity sensor, or physical contact (i.e.,double tap). Combinations of the above can also be used to confirm ordecline calibration. Present principles apply to all speaker housingsparticularly the housings of portable wireless speakers including butnot limited to sound bars, subwoofers, and TVs.

A device includes at least one computer medium that is not a transitorysignal and that in turn includes instructions executable by at least oneprocessor to receive, from at least one capacitance sensor on a wall ofa speaker disposed on a surface, at least one signal. The instructionsare executable to, based at least in part on the signal, retrieve atleast one speaker configuration setting, and to establish a first valueof at least a first audio setting of the speaker based on the speakerconfiguration setting.

In examples, the first audio setting can include a speaker systemchannel configuration, a compression setting, ambient sound attenuation,extra bass, volume, delay, equalization (EQ). Combinations of settingsmay be used.

In another aspect, a method includes receiving a capacitance signal froma sensor on an exterior wall of a housing of a speaker and establishingat least one speaker configuration of the speaker based at least in parton the capacitance signal.

In another aspect, an audio speaker system includes at least a firstaudio speaker associated with a first speaker driver. The system alsoincludes at least one processor configured with instructions forestablishing a first audio configuration of the first audio speakerresponsive to a first signal from a capacitance sensor mounted on asurface of a housing of the first audio speaker that rests on a firstsurface external to the speaker housing.

The details of the present application, both as to its structure andoperation, can be best understood in reference to the accompanyingdrawings, in which like reference numerals refer to like parts, and inwhich:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of an example wireless audio speaker system;

FIG. 2 is a flow chart of example overall logic pertaining to thecentralized system in FIG. 1 ;

FIG. 3 is a screen shot of an example user interface (UI) that may bepresented on a consumer electronics (CE) device to set up speakerlocation determination;

FIG. 4 is a flow chart of example logic for determining speakerlocations in a room;

FIGS. 5-7 are additional screen shots of example UIs related to speakerlocation determination;

FIG. 8 is a flow chart of example logic for establishing audio speakersystem configurations based on whether speakers are indoors or have beenmoved outdoors;

FIG. 9 is a flow chart of example logic for adjusting speaker driversbased on sound barriers in a room;

FIG. 10 is a schematic top plan view of a room illustrating principlesof FIG. 9 ;

FIG. 11 is a flow chart of example logic for adjusting speaker driversbased on listener location in a room;

FIG. 12 is a schematic top plan view of a room illustrating principlesof FIG. 11 ;

FIG. 13 schematically illustrates a switch on an audio system componentfor selecting between indoor and outdoor settings;

FIG. 14 is a screen shot of an example user interface for selectingbetween indoor and outdoor settings;

FIG. 15 is a perspective view of a portable speaker with multiplecapacitor sensors;

FIG. 16 is a schematic diagram of a data structure, also referred toherein as a “library”, that correlates surface type with speakerconfigurations; and

FIG. 17 is a flow chart of example logic for establishing a speakerconfiguration based on the type of surface on which the speaker rests.

DETAILED DESCRIPTION

In addition to the instant disclosure, further details may useDecawave's ultra-wide band (UWB) techniques disclosed in one or more ofthe following location determination documents, all of which areincorporated herein by reference: U.S. Pat. Nos. 9,054,790; 8,870,334;8,677,224; 8,437,432; 8,436,758; and USPPs 2008/0279307; 2012/0069868;2012/0120874. In addition to the instant disclosure, further details onaspects of the below-described rendering including up-mixing and downrendering may use the techniques in any one or more of the followingrendering documents, all of which are incorporated herein by reference:U.S. Pat. Nos. 7,929,708; 7,853,022; USPP 2007/0297519; USPP2009/0060204; USPP 2006/0106620; and Reams, “N-Channel Rendering:Workable 3-D Audio for 4kTV”, AES 135 White paper, New York City 2013.

This disclosure relates generally to computer ecosystems includingaspects of multiple audio speaker ecosystems. A system herein mayinclude server and client components, connected over a network such thatdata may be exchanged between the client and server components. Theclient components may include one or more computing devices that haveaudio speakers including audio speaker assemblies per se but alsoincluding speaker-bearing devices such as portable televisions (e.g.smart TVs, Internet-enabled TVs), portable computers such as laptops andtablet computers, and other mobile devices including smart phones andadditional examples discussed below. These client devices may operatewith a variety of operating environments. For example, some of theclient computers may employ, as examples, operating systems fromMicrosoft, or a Unix operating system, or operating systems produced byApple Computer or Google.

These operating environments may be used to execute one or more browsingprograms, such as a browser made by Microsoft or Google or Mozilla orother browser program that can access web applications hosted by theInternet servers discussed below.

Servers may include one or more processors executing instructions thatconfigure the servers to receive and transmit data over a network suchas the Internet. Or, a client and server can be connected over a localintranet or a virtual private network.

Information may be exchanged over a network between the clients andservers. To this end and for security, servers and/or clients caninclude firewalls, load balancers, temporary storages, and proxies, andother network infrastructure for reliability and security. One or moreservers may form an apparatus that implement methods of providing asecure community such as an online social website to network members.

As used herein, instructions refer to computer-implemented steps forprocessing information in the system. Instructions can be implemented insoftware, firmware or hardware and include any type of programmed stepundertaken by components of the system.

A processor may be any conventional general-purpose single- ormulti-chip processor that can execute logic by means of various linessuch as address lines, data lines, and control lines and registers andshift registers. A processor may be implemented by a digital signalprocessor (DSP), for example.

Software modules described by way of the flow charts and user interfacesherein can include various sub-routines, procedures, etc. Withoutlimiting the disclosure, logic stated to be executed by a particularmodule can be redistributed to other software modules and/or combinedtogether in a single module and/or made available in a shareablelibrary.

Present principles described herein can be implemented as hardware,software, firmware, or combinations thereof; hence, illustrativecomponents, blocks, modules, circuits, and steps are set forth in termsof their functionality.

Further to what has been alluded to above, logical blocks, modules, andcircuits described below can be implemented or performed with ageneral-purpose processor, a digital signal processor (DSP), a fieldprogrammable gate array (FPGA) or other programmable logic device suchas an application specific integrated circuit (ASIC), discrete gate ortransistor logic, discrete hardware components, or any combinationthereof designed to perform the functions described herein. A processorcan be implemented by a controller or state machine or a combination ofcomputing devices.

The functions and methods described below, when implemented in software,can be written in an appropriate language such as but not limited to C#or C++, and can be stored on or transmitted through a computer-readablestorage medium such as a random access memory (RAM), read-only memory(ROM), electrically erasable programmable read-only memory (EEPROM),compact disk read-only memory (CD-ROM) or other optical disk storagesuch as digital versatile disc (DVD), magnetic disk storage or othermagnetic storage devices including removable thumb drives, etc. Aconnection may establish a computer-readable medium. Such connectionscan include, as examples, hard-wired cables including fiber optic andcoaxial wires and digital subscriber line (DSL) and twisted pair wires.

Components included in one embodiment can be used in other embodimentsin any appropriate combination. For example, any of the variouscomponents described herein and/or depicted in the Figures may becombined, interchanged or excluded from other embodiments.

“A system having at least one of A, B, and C” (likewise “a system havingat least one of A, B, or C” and “a system having at least one of A, B.C”) includes systems that have A alone, B alone, C alone, A and Btogether, A and C together, B and C together, and/or A, B, and Ctogether, etc.

Now specifically referring to FIG. 1 , an example system 10 is shown,which may include one or more of the example devices mentioned above anddescribed further below in accordance with present principles. The firstof the example devices included in the system 10 is an example consumerelectronics (CE) device 12. The CE device 12 may be, e.g., acomputerized Internet enabled (“smart”) telephone, a tablet computer, anotebook computer, a wearable computerized device such as e.g.computerized Internet-enabled watch, a computerized Internet-enabledbracelet, other computerized Internet-enabled devices, a computerizedInternet-enabled music player, computerized Internet-enabled headphones, a computerized Internet-enabled implantable device such as animplantable skin device, etc., and even e.g. a computerizedInternet-enabled television (TV). Regardless, it is to be understoodthat the CE device 12 is configured to undertake present principles(e.g. communicate with other devices to undertake present principles,execute the logic described herein, and perform any other functionsand/or operations described herein).

Accordingly, to undertake such principles the CE device 12 can beestablished by some or all of the components shown in FIG. 1 . Forexample, the CE device 12 can include one or more touch-enabled displays14, one or more speakers 16 for outputting audio in accordance withpresent principles, and at least one additional input device 18 such ase.g. an audio receiver/microphone for e.g. entering audible commands tothe CE device 12 to control the CE device 12. The example CE device 12may also include one or more network interfaces 20 for communicationover at least one network 22 such as the Internet, an WAN, an LAN, etc.under control of one or more processors 24. It is to be understood thatthe processor 24 controls the CE device 12 to undertake presentprinciples, including the other elements of the CE device 12 describedherein such as e.g. controlling the display 14 to present images thereonand receiving input therefrom. Furthermore, note the network interface20 may be, e.g., a wired or wireless modem or router, or otherappropriate interface such as, e.g., a wireless telephony transceiver,Wi-Fi transceiver, etc.

In addition to the foregoing, the CE device 12 may also include one ormore input ports 26 such as, e.g., a USB port to physically connect(e.g. using a wired connection) to another CE device and/or a headphoneport to connect headphones to the CE device 12 for presentation of audiofrom the CE device 12 to a user through the headphones. The CE device 12may further include one or more computer memories 28 such as disk-basedor solid-state storage that are not transitory signals. Also, in someembodiments, the CE device 12 can include a position or locationreceiver such as but not limited to a GPS receiver and/or altimeter 30that is configured to e.g. receive geographic position information fromat least one satellite and provide the information to the processor 24and/or determine an altitude at which the CE device 12 is disposed inconjunction with the processor 24. However, it is to be understood thatthat another suitable position receiver other than a GPS receiver and/oraltimeter may be used in accordance with present principles to e.g.determine the location of the CE device 12 in e.g. all three dimensions.

Continuing the description of the CE device 12, in some embodiments theCE device 12 may include one or more cameras 32 that may be, e.g., athermal imaging camera, a digital camera such as a webcam, and/or acamera integrated into the CE device 12 and controllable by theprocessor 24 to gather pictures/images and/or video in accordance withpresent principles. Also included on the CE device 12 may be a Bluetoothtransceiver 34 and other Near Field Communication (NFC) element 36 forcommunication with other devices using Bluetooth and/or NFC technology,respectively. An example NFC element can be a radio frequencyidentification (RFID) element.

Further still, the CE device 12 may include one or more motion sensors(e.g., an accelerometer, gyroscope, cyclometer, magnetic sensor,infrared (IR) motion sensors such as passive IR sensors, an opticalsensor, a speed and/or cadence sensor, a gesture sensor (e.g. forsensing gesture command), etc.) providing input to the processor 24. TheCE device 12 may include still other sensors such as e.g. one or moreclimate sensors (e.g. barometers, humidity sensors, wind sensors, lightsensors, temperature sensors, etc.) and/or one or more biometric sensorsproviding input to the processor 24. In addition to the foregoing, it isnoted that in some embodiments the CE device 12 may also include akinetic energy harvester to e.g. charge a battery (not shown) poweringthe CE device 12.

In some examples, the CE device 12 may function in connection with thebelow-described “master” or the CE device 12 itself may establish a“master”. A “master” is used to control multiple (“n”, wherein “n” is aninteger greater than one) speakers 40 in respective speaker housings,each of can have multiple drivers 41, with each driver 41 receivingsignals from a respective amplifier 42 over wired and/or wireless linksto transduce the signal into sound (the details of only a single speakershown in FIG. 1 , it being understood that the other speakers 40 may besimilarly constructed). Each amplifier 42 may receive over wired and/orwireless links an analog signal that has been converted from a digitalsignal by a respective standalone or integral (with the amplifier)digital to analog converter (DAC) 44. The DACs 44 may receive, overrespective wired and/or wireless channels, digital signals from adigital signal processor (DSP) 46 or other processing circuit.

The DSP 46 may receive source selection signals over wired and/orwireless links from plural analog to digital converters (ADC) 48, whichmay in turn receive appropriate auxiliary signals and, from a controlprocessor 50 of a master control device 52, digital audio signals overwired and/or wireless links. The control processor 50 may access acomputer memory 54 such as any of those described above and may alsoaccess a network module 56 to permit wired and/or wireless communicationwith, e.g., the Internet. The control processor 50 may also access alocation module 57. The location module 57 may be implemented by a UWBmodule made by Decawave or it may be implemented using the Li-Fiprinciples discussed in one or more of the above-referenced patents orby other appropriate techniques including GPS. One or more of thespeakers 40 may also have respective location modules attached orotherwise associated with them. As an example, the master device 52 maybe implemented by an audio video (AV) receiver or by a digital pre-ampprocessor (pre-pro).

As shown in FIG. 1 , the control processor 50 may also communicate witheach of the ADCs 48, DSP 46, DACs 44, and amplifiers 42 over wiredand/or wireless links. In any case, each speaker 40 can be separatelyaddressed over a network from the other speakers.

More particularly, in some embodiments, each speaker 40 may beassociated with a respective network address such as but not limited toa respective media access control (MAC) address. Thus, each speaker maybe separately addressed over a network such as the Internet. Wiredand/or wireless communication links may be established between thespeakers 40/CPU 50. CE device 12, and server 60, with the CE device 12and/or server 60 being thus able to address individual speakers, in someexamples through the CPU 50 and/or through the DSP 46 and/or throughindividual processing units associated with each individual speaker 40,as may be mounted integrally in the same housing as each individualspeaker 40.

The CE device 12 and/or control device 52 of each individual speakertrain (speaker+amplifier+DAC+DSP, for instance) may communicate overwired and/or wireless links with the Internet 22 and through theInternet 22 with one or more network servers 60. Only a single server 60is shown in FIG. 1 . A server 60 may include at least one processor 62,at least one tangible computer readable storage medium 64 such asdisk-based or solid-state storage, and at least one network interface 66that, under control of the processor 62, allows for communication withthe other devices of FIG. 1 over the network 22, and indeed mayfacilitate communication between servers and client devices inaccordance with present principles. Note that the network interface 66may be, e.g., a wired or wireless modem or router, Wi-Fi transceiver,Li-Fi transceiver, or other appropriate interface such as, e.g., awireless telephony transceiver.

Accordingly, in some embodiments the server 60 may be an Internetserver, may include and perform “cloud” functions such that the devicesof the system 10 may access a “cloud” environment via the server 60 inexample embodiments. In a specific example, the server 60 downloads asoftware application to the master and/or the CE device 12 for controlof the speakers 40 according to logic below. The master/CE device 12 inturn can receive certain information from the speakers 40, such as theirlocation from a real time location system (RTLS) such as but not limitedto GPS or Li-Fi or UWB or other technique, and/or the master/CE device12 can receive input from the user, e.g., indicating the locations ofthe speakers 40 as further disclosed below. Based on these inputs atleast in part, the master/CE device 12 may execute the speakeroptimization logic discussed below, or it may upload the inputs to acloud server 60 for processing of the optimization algorithms and returnof optimization outputs to the CE device 12 for presentation thereof onthe CE device 12, and/or the cloud server 60 may establish speakerconfigurations automatically by directly communicating with the speakers40 via their respective addresses, in some cases through the CE device12. Note that if desired, each speaker 40 may include one or morerespective one or more light emitting diode (LED) assemblies 68implementing Li-Fi communication to establish short-range wirelesscommunication among the networked speakers shown. Also, the remotecontrol of the user, e.g., the CE device 12, may include one or more LEDassemblies.

As shown, the speakers 40 are disposed in the enclosure 70 such as aroom, e.g., a living room. For purposes of disclosure, the enclosure 70has (with respect to the example orientation of the speakers shown inFIG. 1 ) a front wall 72, left and right-side walls 74, 76, and a rearwall 78. One or more listeners 82 may occupy the enclosure 70 to listento audio from the speakers 40. One or microphones 80 may be arranged inthe enclosure for generating signals representative of sound in theenclosure 70, sending those signals via wired and/or wireless links tothe CPU 50 and/or the CE device 12 and/or the server 60. In thenon-limiting example shown, each speaker 40 supports a microphone 80, itbeing understood that the one or more microphones may be arrangedelsewhere in the system if desired.

Because of the portability afforded by wireless configurations, one ormore components of the system shown in FIG. 1 , such as one or morespeakers, may be moved outside the enclosure 70 an outside location 90,such as a patio. Principles described further below can automaticallyreconfigure speakers based on whether they are inside or outside.

Disclosure below may make determinations using sonic wave calculationsknown in the art, in which the acoustic waves frequencies (and theirharmonics) from each speaker, given its role as a bass speaker, a treblespeaker, a sub-woofer speaker, or other speaker characterized by havingassigned to it a particular frequency band, are computationally modeledin the enclosure 70 and the locations of constructive and destructivewave interference determined based on where the speaker is and where thewalls 72-78 are. As mentioned above, the computations may be executed,e.g., by the CE device 12 and/or by the cloud server 60 and/or master52.

As an example, a speaker may emit a band of frequencies between 20 Hzand 30 Hz, and frequencies (with their harmonics) of 20 Hz, 25 Hz, and30 Hz may be modeled to propagate in the enclosure 70 with constructiveand destructive interference locations noted and recorded. The waveinterference patterns of other speakers based on the modeled expectedfrequency assignations and the locations in the enclosure 70 of thoseother speakers may be similarly computationally modeled together torender an acoustic model for a particular speaker system physical layoutin the enclosure 70 with a particular speaker frequency assignation. Insome embodiments, reflection of sound waves from one or more of thewalls may be accounted for in determining wave interference. In otherembodiments reflection of sound waves from one or more of the walls maynot be accounted for in determining wave interference. The acousticmodel based on wave interference computations may furthermore accountfor particular speaker parameters such as but not limited toequalization (EQ). The parameters may also include delays, i.e., soundtrack delays between speakers, which result in respective wavepropagation delays relative to the waves from other speakers, whichdelays may also be accounted for in the modeling. A sound track delayrefers to the temporal delay between emitting, using respectivespeakers, parallel parts of the same soundtrack, which temporally shiftsthe waveform pattern of the corresponding speaker. The parameters canalso include volume, which defines the amplitude of the waves from aparticular speaker and thus the magnitude of constructive anddestructive interferences in the waveform. Collectively, a combinationof speaker location, frequency assignation, and parameters may beconsidered to be a “configuration”. A configuration may be establishedto optimize, according to a desired, potentially empirically-determinedstandard of optimization, acoustic wave constructive and destructiveinterference for a particular location in the enclosure 70 given thelocations of the walls and the various frequencies to be assigned to thevarious speakers. The particular location(s) may be the expected oractual location of one or more listener, and the EQs, frequencyassignations, and delays of the various speakers may be further tailoredto the desires or traits of specific individual listeners based onlistener profiles.

The configuration shown in FIG. 1 has a centralized control architecturein which the master device 52 or CE device 12 or other devicefunctioning as a master renders two channel audio into as many channelsare there are speakers in the system, providing each respective speakerwith its channel. The rendering, which produces more channels thanstereo and hence may be considered “up-mixing”, may be executed usingprinciples described in the above-referenced rendering references. FIG.2 describes the overall logic flow that may be implemented using thecentralized architecture of FIG. 1 , in which most if not all of thelogic is executed by the master device.

The logic shown in FIG. 2 may be executed by one or more of the CPU 50,the CE device 12 processor 24, and the server 60 processor 62. The logicmay be executed at application boot time when a user, e.g. by means ofthe CE device 12, launches a control application, which prompts the userto energize the speaker system to energize the speakers 40.

Commencing at block 200, the processor(s) of the master determines roomdimension, the location of each speaker in the system, and number ofspeakers in the room, and the location and if desired identities of eachlistener in the room. This process is described further below. Moving toblock 202, the master selects the source of audio to be played. This maybe done responsive to user command input using, e.g., the device 12.

If the input audio is not two channel stereos, but instead is, e.g.,seven channel audios plus a subwoofer channel (denoted “7.1 audio”), atblock 204 the input audio may be down-mixed to stereo (two channel). Thedown-mixing may be executed using principles described in theabove-referenced rendering references. Other standards for down-mixingmay be used, e.g., ITU-R BS.775-3 or Recommendation 7785. Then,proceeding to block 206 the stereo audio (whether received in stereo ordown-mixed) can be up-mixed to render “N” channels, where “N” is thenumber of speaker drivers in the system. Audio can be rendered for eachspeaker driver based on the respective speaker location (i.e.,perimeter, aerial, sub in the x, y, z domain). The up-mixing can bebased on the current speaker locations as will be explained furthershortly.

Moving to block 208, the channel/speaker output levels are calibratedper description below, preferably based on primary listener location,and then at block 210 system volume is established based on, e.g., roomdimensions, number and location of speakers, etc. The user may adjustthis volume. At block 212 the master sends the respective audio channelsto the respective speakers.

Thus, it may now be appreciated that the speakers 40 do not have to bein a predefined configuration to support a specific audio configurationsuch as 5.1 or 7.1 and do not have to be disposed in the pre-definedlocations of such audio configurations, because the input audio isdown-mixed to stereo and then up-mixed into the appropriate number ofchannels for the actual locations and number of speakers.

FIG. 3 illustrates an embodiment in which the dimensions of theenclosure 70 are manually entered by the user, it being understood thatautomatic means of effecting the same outcome are set forth furtherbelow.

A user interface (UI) may be presented, e.g., on the display 14 of theCE device 12, pursuant to the logic in block 200 of FIG. 2 , in the casein which speaker location determination is intended for two dimensionsonly (in the x-y, or horizontal, plane). FIG. 4 illustrates aspects oflogic that may be used with FIG. 3 . An application (e.g., via Android,iOS, or URL) can be provided to the customer for use on the CE device12.

As shown at 300 in FIG. 3 and at block 400 in FIG. 4 , the user can beprompted to enter the dimensions of the room 70, an outline 70′ of whichmay be presented on the CE device as shown once the user has entered thedimensions. The dimensions may be entered alpha-numerically. e.g., “15feet by 20 feet” as at 302 in FIG. 3 and/or by dragging and dropping thelines of an initial outline 70′ to conform to the size and shape of theroom 70. The application presenting the UI of FIG. 3 may provide areference origin, e.g., the southwest corner of the room. The room sizeis received from the user input at block 402 of FIG. 4 .

In other embodiments discussed further below, room size and shape can bedetermined automatically. This can be done by sending measurement waves(such as Li-Fi transmissions from the LEDs) from an appropriatetransceiver on the CE device 12 and detecting returned reflections fromthe walls of the room 70, determining the distances between transmittedand received waves to be one half the time between transmission andreception times the speed of the relevant wave. Or, it may be executedusing other principles such as imaging the walls and then using imagerecognition principles to convert the images into an electronic map ofthe room.

Moving to block 404, the user may be prompted as at 304 to enter ontothe UI of FIG. 3 at least three fixed locations, in one example, theleft and right ends 306, 308 of a sound bar or TV 310 and the locationat which the user has disposed the audio system subwoofer 312. Fourfixed locations are entered for 3D rendering determinations. Entry maybe effected by touching the display 14 at the locations in the outline70′ corresponding to the requested components. In a Li-Fiimplementation, each fixed location may be associated with a respectiveLi-Fi LED 68 shown in FIG. 1 . The locations are received at block 406in FIG. 4 . The user may also directly input the fact that, forinstance, the sound bar is against a wall, so that renderingcalculations can ignore mathematically possible calculations in theregion behind the wall.

Note that only speakers determined to be in the same room may beconsidered. Other speakers in other rooms can be ignored. Whendetermining the speaker locations, it may first be decided if a 2D or 3Dapproach is to be used. This may be done by knowing how many known offixed locations have been entered. Three known locations yield a 2Dapproach (all speakers are more or less residing in a single plane).Four known locations yield a 3D approach. Note further that the distancebetween the two fixed sound bar (or TV) locations may be known by themanufacturer and input to the processor automatically as soon as theuser indicated a single location for the sound bar. In some embodiments,the subwoofer location can be input by the user by entering the distancefrom the sound bar to the subwoofer. Moreover, if a TV is used for twoof the fixed locations, the TV may have two locators mounted on it witha predetermined distance between the locators stored in memory, similarto the sound bar. Yet again, standalone location markers such as LEDs orUWB tags can be placed within the room (e.g., at the corner of room,room boundary, and/or listening position) and the distance from eachstandalone marker to the master entered into the processor.

When communication is established among the speakers in the room 70, atblock 408 in FIG. 4 the master device and/or CE device 12 and/or otherdevice implements a location module according to the locationdetermination references above, determining the number of speakers inthe room 70 and their locations, and if desired presenting the speakersat the determined locations (along with the sound bar 310 and subwoofer213) as shown at 314A-D in FIG. 3 . The lines 316 shown in FIG. 3illustrate communication among the speakers 310, 312, 314 and may or maynot be presented in the UI of FIG. 3 .

In an example “automatic” implementation, a component in the system suchas the master device or CE device 12 originates two-way UWB or Li-Firanging (or using GPS modules on each speaker). When ranging is used,range and direction to each speaker from the originating device aredetermined using triangulation and the distance-time-speed algorithmdescribed above. If desired, multiple rounds of two-way ranging can beperformed with the results averaged for greater accuracy.

The two-way ranging described above may be affected by causing the CEdevice 12 (or other device acting as a master for purposes of speakerlocation determination) to receive a poll message from an anchor point.The CE device 12 sends a response message to the poll message. Thesemessages can convey the identifications associated with eachtransmitter. In this way, the number of speakers can be known.

The polling anchor point may wait a predetermined period known to the CEdevice 12 and then send a final poll message to the CE device 12, whichcan then, knowing the predetermined period from receipt of its responsemessage that the anchor point waited and the speed of the signals, andthe time the final message was received, determine the range to theanchor point.

While FIGS. 3 and 4 are directed to finding the locations of thespeakers in two dimensions, their heights (elevations) in the room 70may also be determined for a three-dimensional location output. Theheight of each speaker can be manually input by the user or determinedusing an altimeter associated with each speaker or determined byimplementing a LED 68, e.g., the CE device 12 as three integratedcircuits with respective LEDs distanced from each other by knowndistances, enabling triangulation in three dimensions. Other techniquesfor finding z-axis locations such as UWB, etc. may be used.

The primary listener location may be then determined according todiscussion below. The number of speakers and their locations in the roomare now known. Any speakers detected as above that lie outside the roommay be ignored. A GUI may be presented on the CE device of the usershowing the room and speakers therein and prompting the user to confirmthe correctness of the determined locations and room dimensions.

FIGS. 5 and 6 illustrate aspects of an implementation of the 3D locationdetermination. These figures may be presented as UIs on the CE device12. Four known locations may be provided to determine the location ofeach speaker in three dimensions. In the example shown in FIG. 5 , theuser has input the locations 500, 502 associated with a sound bar/TV 504and the location of the subwoofer 506. The user has also identified(e.g., by touching the display 14 of the CE device 12 at the appropriatelocations) two corners 508, 510 of the room 70, preferably corners inwhich locators such as LEDs 68 have been positioned. Determination ofthe number of speakers and locations in 3D using triangulation discussedabove and the techniques described in the above-referenced locationdetermination references is then made. Note that while FIGS. 5 and 6respectively show a top view and a side view of the room 70 on thedisplay 14 in two separate images, a single 3D image composite may bepresented.

FIG. 7 illustrates yet another UI that can be presented on the CE device12 in which the user has entered, at 700, the expected location of alistener in the room 700. Or, the location 700 can be automaticallydetermined as described further below using transmissions. Yet again,for purposes of up-mixing according to the rendering referencesincorporated above, a default location may be assumed, e.g., thegeometric center of the room 70, or alternatively about ⅔ of thedistance from the front of the room (where the sound bar or TV isusually located) to the rear of the room.

Once the number and locations of the speakers are known, the up mixingat block 206 may be executed using the principles discussed in theabove-referenced rendering documents. Specifically, the stereo audio(either as received stereo or resulting from down-mixing of non-stereoinput audio at block 204) is up-mixed to, as an example, N.M audio,wherein M=number of subwoofers (typically one) and N=number of speakerdrivers other than the sub-woofer. As detailed in the renderingdocuments, the up-mixing uses the speaker locations in the room 70 todetermine which of the “N” channels to assign to each of the respectiveN speaker drivers, with the subwoofer channel being always assigned tothe subwoofer. The listener location 700 shown in FIG. 7 can be used tofurther refine channel delay, EQ, and volume based on the speakercharacteristics (parameters) to optimize the sound for the listenerlocation.

One or more measurement microphones, such as may be established by themicrophones 80 in FIG. 1 , may be used if available to further calibratethe channel characteristics. This may be made based on informationreceived from the individual speakers/CPU 50 indicating microphones areon the speakers, for example.

If measurement microphones are available, the user can be guided througha measurement routine. In one example, the user is guided to cause eachindividual speaker in the system to emit a test sound (“chirp”) that themicrophones 80 and/or microphone 18 of the CE device 12 detect andprovide representative signals thereof to the processor or processorsexecuting the logic, which, based on the test chirps, can adjust speakerparameters such as EQ, delays, and volume.

The example above uses a centralized master device to up-mix and rendereach of the “N” audio channels, sending those channels to the respectivespeakers. When wireless connections are used, and bandwidth is limited,a distributed architecture may be used, in which the same stereo audiofrom a master is sent to each speaker, and each speaker renders, fromthe stereo audio, its own respective channel. Details of thisalternative architecture are set forth in the above-referenced U.S. Pat.No. 9,826,332.

In determining distances using ranging, one or more measurement signalssuch as light beams may be transmitted, and reflections received. Todetermine distance the following equation may be used:D=c(t ₁ −t ₀)

where c=speed of light, t₁ is time of receipt, and t₀ is time oftransmission.

It may then be assumed that for each receiver, the distance to the wallclosest to that receiver a midpoint of a projected planar surface. Themidpoints may be communicated to a determination processor (which may beimplemented by any of the processors herein) which projects respectiveplanes from each midpoint. The projected planar surfaces will intersecteach other with the intersections defining the corners of the enclosure70 and the portions of the projected planes within the corners definingthe walls of the enclosure.

The above is but one simplified method for mapping the wall locations ofthe enclosure 70. More complex methods may be used. For example, theprocess above can be repeated multiple times to refine the walllocations. Additional reflections after time t₁ at each receiver mayalso be used to ascertain whether a receiver's initial reflection isindeed from a wall or from an intervening object. Or, the transmittingassembly may be mounted on a gimbal to send multiple transmissions atmultiple orientations such that the reflections detected by thereceivers at some orientations may be received sooner than reflectionsreceived at other orientations, with the further reflection beingassumed to be a wall and the earlier reflection assumed to be from anintervening object between the receiver and wall. Instead of a gimbal tosteer the transmitting assembly, a micro-electrical mechanical system(MEMS) may be used.

Yet again, in embodiments in which each location assembly knows itslocation and the locations of other assemblies by virtue of GPSinformation being communicated between the assemblies or by other means(e.g., manual location entry by an installer), the locations of theassemblies may be used in the computation of wall locations to ferretout false indications of wall locations arising from reflections fromintervening objects. Yet again, it may be assumed, for the same purposethat each receiver is more or less at the same distance from its closestwall as the opposite receiver.

Yet again, a combination of manual and automatic mapping may be used.For instance, a user may be presented with a UI such as those describedabove to indicate the locations of the walls of the enclosure, withsubsequent reflections determined to have come from the walls based onthe known locations of the LED assemblies being ignored and otherreflections being inferred to be from intervening objects such aslisteners or audio speakers. Similarly, the user may use a touch displayto touch a presentation of an estimated model of the enclosure toindicate where audio speakers and/or listeners are, with reflectionsfrom those locations being ignored by the LED assemblies and otherreflections inferred to be from the walls, thereby refining the map ofthe enclosure.

Note that when mapping, reflections indicating locations in the sameflat plane, potentially satisfying a size criteria that discriminatesbetween larger walls and smaller rectangular objects, may be mapped aswalls of the enclosure. That is, feature recognition may be used torecognize that a series of reflections at a given receiver or receiversall lie in the same plane, and that the plane is sufficiently large tobe inferred to be a wall. In addition, or alternatively, the featurerecognition may be based on the type of reflection received. Forexample, it may be assumed that a strong reflection (higher amplitude)comes from a hard speaker surface, whereas a less strong reflectioncomes from a matte-painted wall. Other feature vectors may be used.Return signal characteristics may be, as discussed above, anexceptionally high amplitude as may be reflected by reflectors or tagsengaged with the audio speakers. In contrast other points of reflectionwith a second type of return signal characteristic may be mapped ashuman listener locations.

The second type of return signal characteristic may be a relatively lowamplitude reflection signal as may be produced by a surface such ashuman skin that is softer than an audio speaker or a wall.

FIG. 8 illustrates logic for establishing audio configurations in aspeaker system depending on whether the system is indoors or outdoors.Commencing at block 800, the number of speaker drivers and theirorientations (i.e., axis of sound cone projected by the associatedspeaker, in 3D if desired) are identified. This may be done using any ofthe techniques described above, e.g., by receiving user input of thisinformation during setup or using any of the automatic methods describedherein. Note that some speakers may have multiple drivers for a greaterthan stereo effect. Speaker driver configuration is discussed furtherbelow.

Moving to block 802, a sensing mechanism is monitored, if need be byfirst activating it, for determining whether part or all of the speakersystem is indoors or outdoors. Activation may be initiated by, e.g.,tapping or double tapping an audio system component such as anydescribed herein or moving, if desired in a certain way, an audio systemcomponent such as any described herein, with such movement being sensedand correlated to “activate indoor/outdoor determination”.

In one example, activation can entail activating a microphone such asany of the microphones described herein to receive a voice commandindicating “indoor” or “outdoor”. In another example this can entailactivating a microphone such as any of the microphones described hereinto receive a voice command indicating that any of the processorsdescribed herein is to automatically determine whether the audio systemis indoors or outdoors.

A number of techniques may be used to do this. For example, signals fromone or more light sensors on or near respective speakers can bereceived, indicating illumination levels correlated with indoors(typically lower levels) or outdoors (typically higher levels fordaytime and lower than indoors for night). Or, signals from one or moremicrophones on or near respective speakers can be received, digitized,and compared against a database of audio fingerprints to determinewhether sounds are being received such as bird chirps that arecorrelated to outdoors or cooking sounds normally correlated to indoors,etc. As further examples, signals from one or more moisture sensors onor near respective speakers can be received, with relatively highermoisture levels indicating outdoors and relatively lower moisture levelsindicating indoors. Still further, signals from one or more cameras onor near respective speakers can be received, digitized, and using imagerecognition compared against a database of images that correlates someimages (such as of stars, trees, etc.) to outdoors and other images(such as walls, kitchen appliances, etc.) to indoors.

Yet again, briefly referring to FIG. 13 , a mechanical switch 1300 canbe provided on an audio system component 1302 such as any of the audiosystem components described herein, and can be manipulated to indicateindoors (by, e.g., moving the switch to an “indoor” position 1304) oroutside or outdoors (by, e.g., moving the switch to an “outside”position 1306).

Or, briefly referring to FIG. 14 , a user interface 1400 may bepresented on an audio system display 1402 such as any described hereinwith an indoor selector 1404 and an outside or outdoors selector 1406,with one of the selectors 1404, 1406 being selectable to establishwhether the system should be configured with indoor or outdoor settingsas described below. If desired, as shown in FIG. 14 when indoor 1404 isselected, a depiction 1408 may be presented showing icons 1410 ofspeakers and their locations relative to walls 1412 of the room in whichthey are located. Icons 1414 may also be presented showing locations oflisteners in the room. Combinations of the above techniques may be usedto indicate indoors or outdoors. For example, sensed movement of adevice such as a speaker may be followed by a voice command to confirmor decline an identification of “indoors” or “outdoors” andcorresponding speaker calibration.

Returning to FIG. 8 , decision diamond 804 is used to indicate that if“outdoors” is determined, logic advances to block 806 et seq. toautomatically establish audio settings for the system appropriate foroutdoor operation, whereas if “indoors” is determined, logic advances toblock 816 et seq. to establish audio settings for the system appropriatefor indoor operation.

At block 806, audio channels are established according to how manyspeakers are in the outdoor environment. If only a single speaker isoutdoors, input audio (e.g., stereo) is converted to mono and played onthe sole outdoor speaker. If two speakers are outdoors, stereo is outputfor play of one channel on one of the speakers and the other channel onthe other speaker. If three speakers are outdoors, input audio, ifstereo, for example, is converted to left, center, and right channelsfor play of the three channels on the three respective speakers.Similarly, if four speakers are outdoors, input audio, if stereo, forexample, is converted to four channels (for example, left front, rightfront, left rear, right rear) for play of the four channels on the fourrespective speakers. In general, input stereo may be up-converted toN-channel audio for play on N outdoors speakers.

Moving to block 808, dynamic audio compression (in some examples,implemented by an audio compressor) is set to an outdoor value. Audiocompression is a signal processing operation that reduces the volume ofloud sounds or amplifies quiet sounds thus reducing or compressing anaudio signal's dynamic range. For outdoor operation, low compressionrelative to the value that would be set for indoor operation may be usedbecause ambient noise out of doors may typically be higher than quieterambient atmosphere indoors. Other settings heuristics may be used.

Proceeding to block 810, “live sound”, the amount of ambient noise thatis processed relative to the primary demanded audio, is set to a valueappropriate for outdoor operation. An example value would be a settingto process less ambient noise when outdoors than when in an indoorenvironment. At block 812 an extra base audio setting may be establishedat a value appropriate for outdoor operation. For example, more extrabass (higher value) may be established for outdoor operation than wouldbe established for indoor operation. Likewise, at block 814 anequalization (EQ) setting value and loudness curve may be establishedthat is more appropriate for outdoor operation. As an example, an EQvalue that results in more bass compared to treble than an EQ value thatresults in relatively less bass compared to treble may be establishedfor outdoor operation, with an EQ value that results in relatively lessbass compared to treble may be established for indoor operation. Aloudness curve more appropriate for outdoor operation also may beestablished.

On the other hand, when indoor operation is identified at decisiondiamond 804, the logic may move to block 816 to determine the directionfrom a user (listener) to the audio system or a speaker thereof (such asthe center channel speaker). At block 818 the distance between the user(listener) and system or audio speaker may also be determined. Locationsof nearby barriers such as walls may be determined at block 820, ifdesired for each indoor speaker.

Blocks 822-830 are analogous to blocks 806-814 described above, exceptthat indoor setting values are established in blocks 822-830. Thus, atblock 822 audio channels are established according to how many speakersare in the indoor environment. Moving to block 824, dynamic audiocompression (in some examples, implemented by an audio compressor) isset to an indoor value. Proceeding to block 826, “live sound” is set toa value appropriate for indoor operation. At block 828 an extra baseaudio setting may be established at a value appropriate for indooroperation. For example, less extra bass (lower value) may be establishedfor indoor operation than would be established for outdoor operation.Likewise, at block 830 an equalization (EQ) setting value and loudnesscurve may be established that are more appropriate for indoor operation.

FIGS. 9-12 illustrate additional principles that may be implemented forindoor operation. Commencing at block 900, the number of speaker driversand their orientations (i.e., axis of sound cone projected by theassociated speaker, in 3D if desired) are identified. This may be doneusing any of the techniques described above, e.g., by receiving userinput of this information during setup or using any of the automaticmethods described herein. Note that some speakers may have multipledrivers for a greater than stereo effect. Speaker driver configurationis discussed further below.

Moving to block 902, a sensing mechanism is monitored, if need be byfirst activating it, for determining whether part or all of the speakersystem is indoors or outdoors. Activation may be initiated by, e.g.,tapping or double tapping an audio system component such as anydescribed herein or moving, if desired in a certain way, an audio systemcomponent such as any described herein, with such movement being sensedand correlated to “activate indoor/outdoor determination”.

Assuming that “indoor” is identified at block 902, the logic moves toblock 904. At block 904 locations of nearby barriers such as walls maybe determined, if desired for each indoor speaker, as discussed above inrelation to block 820 of FIG. 8 and description of wall locationidentification in FIGS. 1-7 . Proceeding to block 906, the speakerdrivers are adjusted, for each speaker if desired, such that the centerchannel audio cone. i.e., direction in which the center channel isbroadcast from the speaker, faces a first direction, in this case, awayfrom the closest barrier to the speaker. The left and right channels arethen adjusted accordingly at block 908 to emit sound to the left andright of the new direction of the center channel.

FIG. 10 illustrates. An audio speaker 1000 may have multiple drivers1002, 1004, 1006 for a greater than stereo effect. In the example shown,the speaker 1000 has three perimeter drivers, i.e., the perimeterdrivers are in the same horizontal or x-y plane. It is to be understoodthat the speaker 1000 may also have three height drivers as well, i.e.,three drivers arranged in a vertical plane.

As shown, responsive to a nearest wall 1008 being detected, the leftchannel driver 1002 is moved as indicated by the arrow 1010 to be thecenter channel driver which projects center channel sound outward alonga sonic axis oriented directly away from the wall 1008. The other arrowsin FIG. 10 indicate that the formerly center channel is rotated to theright and the former right channel is rotated to be the left channeldriver. Similar principles may be used for height drivers, withup-rendering used to create height. In general, N-channel audio iscreated to match the number of N drivers. Note that EQ change caninclude crossover frequencies for each particular driver, and that theheight crossover frequencies may be different from the perimetercrossover frequencies.

The above rotation may be affected by mounting the speaker 1000 on avertically-oriented axle and rotating the axle using a motor such as aDC stepper motor. Or, the rotation may be affected electronically, byshifting center channel audio from one otherwise stationary driver toanother otherwise stationary driver to establish the channeldirectionality described above.

FIGS. 11 and 12 illustrate that alternative to directing the centerchannel sound axis away from a wall, it may be directed toward alistener. Commencing at block 1100, the number of speaker drivers andtheir orientations (i.e., axis of sound cone projected by the associatedspeaker, in 3D if desired) are identified in accordance with disclosureabove. Moving to block 1102, a sensing mechanism is monitored, if needbe by first activating it, for determining whether part or all of thespeaker system is indoors or outdoors. Assuming that “indoor” isidentified at block 1102, the logic moves to block 1104. At block 1104locations of a nearby listener is identified, if desired for each indoorspeaker (in which case the listener of multiple detected listeners whois closest to the speaker is selected for that speaker). For example,information from blocks 816 and 818 as discussed above in relation toblock 820 of FIG. 8 and description of listener location identificationin FIGS. 1-7 may be used.

Proceeding to block 1106, the speaker drivers are adjusted, for eachspeaker if desired, such that the center channel audio cone, i.e.,direction in which the center channel is broadcast from the speaker,faces a second direction different from the first direction used for thewall test of FIGS. 9 and 10 , in this case, toward the listener. Theleft and right channels are then adjusted accordingly at block 1108 toemit sound to the left and right of the new direction of the centerchannel.

FIG. 12 illustrates. An audio speaker 1200 may have multiple drivers1202, 1204, 1206 for a greater than stereo effect. In the example shown,the speaker 1200 has three perimeter drivers, i.e., the perimeterdrivers are in the same horizontal or x-y plane. It is to be understoodthat the speaker 1200 may also have three height drivers as well, i.e.,three drivers arranged in a vertical plane.

As shown, responsive to a nearest listener 1208 being detected, the leftchannel driver 1202 is moved as indicated by the arrow 1210 to be thecenter channel driver which projects center channel sound outward alonga sonic axis oriented directly toward the listener 1208. The otherarrows in FIG. 12 indicate that the formerly center channel is rotatedto the right and the former right channel is rotated to be the leftchannel driver. Similar principles may be used for height drivers, withup-rendering used to create height. In general, N-channel audio iscreated to match the number of N drivers. Note that EQ change caninclude crossover frequencies for each particular driver, and that theheight crossover frequencies may be different from the perimetercrossover frequencies.

In lieu of or in addition to the above-described outdoor/indoorcalibration to establish speaker configuration, FIGS. 15-17 illustrate atechnique for automatically establishing speaker configurations based onthe type of surface on which the speaker rests. The technique of FIGS.15-17 may be initiated using any of the methods described above.

FIG. 15 shows a speaker housing 1500 which contains various audiospeaker components described above. On one or more surfaces or walls1502 of the housing 1500, one or more capacitance sensors 1504 aredisposed. In the example shown, a single sensor 1504 is provided foreach respective one of four walls 1502, it being understood that morethan one sensor per wall may be provided and that any number of wallsmay be provided with sensors depending on anticipated placements of thespeaker housing 1500. When a capacitance sensor 1504 is disposed on theground or table top or other surface on which the speaker housing rests,the sensor generates a signal representative of the electricalcapacitance of the surface on which the speaker rests.

FIG. 16 schematically shows an example data structure that can be usedto correlate signals from the capacitance sensor(s) 1504 in FIG. 15 tospeaker configurations. It is to be understood that a column 1600 maylist sensor signal ranges per se, which indicate surface type, or mayindicate surface type directly, which may be derived from a preliminarystep in which sensor signal is correlated to surface type. In eithercase, sensor signals, typically by range of indicated capacitance, canbe associated with surface types (and thus with speaker configurations)through experimentation, by placing a speaker with a capacitance sensoron various known surface types and noting, for each surface type (e.g.,concrete, hardwood, grass, dirt, etc.) the signal output by thecapacitance sensor.

The data structure of FIG. 16 correlates each sensor signal bandrepresenting a respective surface type to one or more speakerconfiguration settings such as EQ 1602, delay 1604, and volume 1606.Other speaker configuration settings correlated in the data structure tosurface type include speaker system channel configuration, compressionsettings, ambient sound attenuation, and extra bass.

Thus, by entering the data structure using the signal output by a sensor1504, the corresponding speaker configuration can be retrieved.

FIG. 17 illustrates. Commencing at block 1700, capacitance signal(s) arereceived from one or more of the sensors 1504 that are in contact withthe ground by virtue of a person having placed the respective wall 1502of the speaker on the ground. The data structure of FIG. 16 is enteredat block 1702 using the capacitance signal from the sensor (orequivalently the surface type of the signal is first correlated to asurface type) to retrieve the speaker configuration settings that havebeen associated with the surface type. Those speaker configurationsetting(s) are then applied to the speaker at block 1704.

While particular techniques are herein shown and described in detail, itis to be understood that the subject matter which is encompassed by thepresent invention is limited only by the claims.

What is claimed is:
 1. A device comprising: at least processorconfigured with instructions to: receive, from at least one sensor on awall of a speaker disposed on a surface, at least one signalrepresenting a type of the surface on which the speaker is disposed;based at least in part on the signal, identify at least one speakerconfiguration at least in part using a data structure correlatingsignals from the at least one sensor to speaker configuration, orcorrelating signals from the at least one sensor to surface type andcorrelating surface type to speaker configuration, the at least onespeaker configuration comprising at least one speaker setting other thanvolume; and establish the speaker configuration on the speaker such thatthe speaker emits audio according to the at least one speaker setting.2. The device of claim 1, comprising the sensor.
 3. The device of claim1, comprising the speaker.
 4. The device of claim 1, wherein the speakerconfiguration comprises a speaker system channel configuration.
 5. Thedevice of claim 1, wherein the speaker configuration comprises acompression setting.
 6. The device of claim 1, wherein the speakerconfiguration comprises extra bass.
 7. The device of claim 1, whereinthe speaker configuration comprises equalization (EQ).
 8. The device ofclaim 1, wherein the speaker configuration comprises ambient soundattenuation.
 9. The device of claim 1, wherein the instructions areexecutable to: identify at least one speaker configuration at least inpart using a data structure correlating signals from the at least onesensor to speaker configuration.
 10. A method, comprising: receiving asignal from a sensor on an exterior wall of a housing of a speaker thatrests against a supporting surface such that the signal depends on atype of the supporting surface; and establishing at least one speakerconfiguration other than volume of the speaker based at least in part onthe signal at least in part using a data structure correlating signalsfrom the sensor to speaker configuration, or correlating signals fromthe sensor to surface type and correlating surface type to speakerconfiguration, the speaker configuration comprising at least one speakersetting.
 11. The method of claim 10, comprising: establishing at leastone speaker configuration of the speaker based at least in part on thesignal at least in part using a data structure correlating signals fromthe sensor to speaker configuration.
 12. The method of claim 10, whereinthe speaker configuration comprises a speaker system channelconfiguration.
 13. The method of claim 10, wherein the speakerconfiguration comprises a compression setting.
 14. The method of claim10, wherein the speaker configuration comprises ambient soundattenuation.
 15. The method of claim 10, wherein the speakerconfiguration comprises extra bass.
 16. The method of claim 10, whereinthe speaker configuration comprises equalization (EQ).
 17. The method ofclaim 10, wherein the speaker configuration comprises delay.
 18. Themethod of claim 10, wherein the signal represents capacitance.
 19. Thedevice of claim 1, wherein the instructions are executable to: identifyat least one speaker configuration at least in part using a datastructure correlating signals from the at least one sensor to surfacetype and correlating surface type to speaker configuration.
 20. Themethod of claim 10, comprising: establishing at least one speakerconfiguration of the speaker based at least in part on the signal atleast in part using a data structure correlating signals from the sensorto surface type and correlating surface type to speaker configuration.21. An audio speaker system, comprising: at least a first audio speaker;and at least one processor configured with instructions for:establishing a first audio configuration of the first audio speakerresponsive to a first signal from a first sensor mounted on a first wallof a housing of the first audio speaker, the first audio configurationcomprising plural settings other than volume; and establishing a secondaudio configuration of the first audio speaker responsive to a secondsignal from a second sensor mounted on a second wall of the housing ofthe first audio speaker, the second audio configuration comprisingplural settings other than volume with values different from values ofat least some of the plural settings of the first audio configuration.22. The audio speaker system of claim 21, comprising plural capacitancesensors mounted on respective surfaces of the housing.